Absence of tissue-bound semicarbazide-sensitive amine oxidase activity in carp tissues

We have previously reported that carp (Cyprinus carpio) tissue mitochondria contain a novel form of monoamine oxidase (MAO), which belongs neither to MAO-A nor to MAO-B of the mammalian enzyme. This conclusion results from the findings that the carp MAO was equally sensitive to a selective MAO-A inhibitor clorgyline and to the MAO-B selective inhibitor l-deprenyl, when tyramine, a substrate for both forms, serotonin or beta-phenylethylamine, a substrate for either A or B-form of mammalian MAO, was used. In the present study, we tried to detect another amine oxidase, termed tissue-bound semicarbazide-sensitive amine oxidase (SSAO), activity in carp tissues. As definition of SSAO was used, such as insensitivity to inhibition of the kynuramine oxidizing activity by an MAO inhibitor pargyline and high sensitivity to the SSAO inhibitor semicarbazide. The results indicated that the oxidizing activity was selectively and almost completely inhibited by 0.1 mM pargyline alone or a combination of 0.1 mM pargyline plus 0.1 mM semicarbazide, but not by 0.1 mM semicarbazide alone. We also tried to detect any SSAO activity by changing experimental conditions, such as lower incubation temperature, higher enzyme protein concentration, a lower substrate concentration and different pH's in the reaction, as the enzyme source. However, still no SSAO activity could be detected in the tissues. These results conclusively indicate that carp tissues so far examined do not contain SSAO activity.     

Topological probes of monoamine oxidases A and B in rat liver mitochondria: inhibition by TEMPO-substituted pargyline analogues and inactivation by proteolysis

TEMPO-substituted pargyline analogues differentially inhibit recombinant human monoamine oxidase A (MAO A) and B (MAO B) in intact yeast mitochondria, suggesting these membrane-bound enzymes are located on differing faces of the mitochondrial outer membrane [Upadhyay, A., and Edmondson, D. E. (2009) Biochemistry 48, 3928]. This approach is extended to the recombinant rat enzymes and to rat liver mitochondria. The differential specificities exhibited for human MAO A and MAO B by the m- and p-amido TEMPO pargylines are not as absolute with the rat enzymes. Similar patterns of reactivity are observed for rat MAO A and B in mitochondrial outer membrane preparations expressed in Pichia pastoris or isolated from rat liver. In intact yeast mitochondria, recombinant rat MAO B is inhibited by the pargyline analogue whereas MAO A activity shows no inhibition. Intact rat liver mitochondria exhibit an inhibition pattern opposite to that observed in yeast where MAO A is inhibited and MAO B activity is unaffected. Protease inactivation studies show specificity in that MAO A is sensitive to trypsin whereas MAO B is sensitive to β-chymotrypsin. In intact mitochondrial preparations, MAO A is readily inactivated in rat liver but not in yeast upon trypsin treatment and MAO B is readily inactivated by β-chymotrypsin in yeast but not in rat liver. These data show MAO A is oriented on the cytosolic face and MAO B is situated on the surface facing the intermembrane space of the mitochondrial outer membrane in rat liver. The differential mitochondrial outer membrane topology of MAO A and MAO B is relevant to their inhibition by drugs designed to be cardioprotectants or neuroprotectants.     

Inhibition of monoamine oxidase activity by antidepressants and mood stabilizers

OBJECTIVE: Monoamine oxidase (MAO), the enzyme responsible for metabolism of monoamine neurotransmitters, has an important role in the brain development and function, and MAO inhibitors have a range of potential therapeutic uses. We investigated systematically in vitro effects of pharmacologically different antidepressants and mood stabilizers on MAO activity. Methods: Effects of drugs on the activity of MAO were measured in crude mitochondrial fraction isolated from cortex of pig brain, when radiolabeled serotonin (for MAO-A) or phenylethylamine (for MAO-B) was used as substrate. The several antidepressants and mood stabilizers were compared with effects of well known MAO inhibitors such as moclobemide, iproniazid, pargyline, and clorgyline. Results: In general, the effect of tested drugs was found to be inhibitory. The half maximal inhibitory concentration, parameters of enzyme kinetic, and mechanism of inhibition were determined. MAO-A was inhibited by the following drugs: pargyline > clorgyline > iproniazid > fluoxetine > desipramine > amitriptyline > imipramine > citalopram > venlafaxine > reboxetine > olanzapine > mirtazapine > tianeptine > moclobemide, cocaine > lithium, valproate. MAO-B was inhibited by the following drugs: pargyline > clorgyline > iproniazid > fluoxetine > venlafaxine > amitriptyline > olanzapine > citalopram > desipramine > reboxetine > imipramine > tianeptine > mirtazapine, cocaine > moclobemide, lithium, valproate. The mechanism of inhibition of MAOs by several antidepressants was found various. Conclusions: It was concluded that MAO activity is acutely affected by pharmacologically different antidepressants at relatively high drug concentrations; this effect is inhibitory. There are differences both in inhibitory potency and in mechanism of inhibition between both several drugs and the two MAO isoforms. While MAO inhibition is not primary biochemical effect related to their therapeutic action, it can be supposed that decrease of MAO activity may be concerned in some effects of these drugs on serotonergic, noradrenergic, and dopaminergic neurotransmission.     

The oxidation of adrenaline and noradrenaline by the two forms of monoamine oxidase from human and rat brain

The selective monoamine oxidase inhibitors clorgyline and (−)-deprenyl were used to study the distribution of monoamine oxidase-A and -B (MAO-A, MAO-B) activities towards (−)-noradrenaline and (+),(−)-adrenaline in homogenates from seven different regions of human brain. The activities towards 5-hydroxytryptamine and 2-phenethylamine, which are essentially specific substrates for the A- and B-forms, respectively, under the conditions used in this work, were also determined. Noradreanline and adrenaline were substrates for both forms of the enzyme in all regions studied. The total MAO activity was found to be highest in the hypothalamus and lowest in the cerebellar cortex. Use of the selective MAO inhibitors clorgyline and (−)-deprenyl also showed adrenaline and noradrenaline to be substrates for both forms of the enzyme in rat brain. In human cerebral cortex and rat brain the two forms were found to have similar K_m-values and maximum velocities towards adrenaline. These values for the two forms were also found to be similar in human cerebral cortex when noradrenaline was used as the substrate. In contrast MAO-A showed a significantly lower K_m and a higher maximum velocity towards noradrenaline in rat brain. These results suggest that the rat may not provide a close model of the human for studies on the effects of MAO inhibitors on brain noradrenaline metabolism.     

PHOSPHOPROTEIN PHOSPHATASE OF PINEAL GLAND: SOME PROPERTIES OF THE ENZYME AND THE IDENTIFICATION OF AN ENDOGENOUS ACTIVATOR

Abstract— Both soluble and insoluble fractions of rat pineal glands catalyze the dephosphorylation of phosphohistone. The phosphoprotein phosphatase in cytosol as well as in insoluble fraction is inhibited by ZnCl₂ and NaF. Guanosine triphosphate, ATP and MnCl₂ activate the soluble enzyme but not the enzyme in the insoluble fraction suggesting that with solubilization from membranes some unfunctional changes of the enzyme may occur. Fractionation of the soluble enzyme preparation revealed the existence of two forms of enzyme differing in molecular weight. These two forms can be further differentiated by their sensitivities to MnCl₂ and deoxycholate. A thermostable factor which activates the soluble but not the insoluble enzyme was demonstrated in both beef and rat pineal glands. The thermostable factor is protein in nature because it is nondialyzable and trypsin labile. Whether in vivo the endogenous activator mediates the regulation of the phosphoprotein phosphatase in pineal remains to be investigated.     

Modification of Morphine-induced Hyperlocomotion and Antinociception in Mice by Clorgyline,a Monoamine Oxidase-A Inhibitor

We evaluated the effects of pretreatment with clorgyline, an irreversible monoamine oxidase (MAO)-A inhibitor, on morphine-induced hyperlocomotion and antinociception. A single administration of morphine (30 mg/kg, i.p.) to male ICR mice induced a hyperlocomotion. ANOVA analysis revealed the statistical significance of the morphine effect on horizontal locomotion and of the clorgyline pretreatment × morphine interaction effect, but not of the effect of clorgyline pretreatment. The initial (5 min after challenge) phase of morphine actions vs. saline challenge appeared as if morphine had a strong inhibitory effect on locomotor activity in combination with different doses of clorgyline. The mice administered with morphine in combination of clorgyline (1 and 10 mg/kg) did not show any stereotypic behaviors. Clorgyline at a dose of 0.1 mg/kg but not other doses tested significantly potentiated morphine-induced antinociception evaluated by tail flick but not hot plate test. During the measurements of locomotor activity and antinociception, clorgyline at doses of 1 and 10 mg/kg significantly inhibited monoamine metabolism through MAO. These results suggest that clorgyline showed an inhibitory effect on morphine-induced hyperlocomotion, but not antinociception, through MAO inhibition. There is not a possibility that clorgyline pretreatment enhanced morphine action on motor activity, resulting in the abnormal behavior from hyperlocomotion to stereotypic movements.     

A new type of mitochondrial monamine oxidase distinct from type-A and type-B

The characteristics of mitochondrial monoamine oxidase (MAO) in carp liver were studied with MAO inhibitors and substrates. This enzyme was thermolabile, but was stabilized in the presence of bovine serum albumin. With clorgyline and deprenyl, single-sigmoidal curves for inhibition of the activity towards tyramine or 5-hydroxytryptamine were obtained; the sensitivities to the two inhibitors were identical. The activity towards β-phenylethylamine was not completely inhibited by clorgyline or deprenyl, but the remaining activity was inhibited by semicarbazide and the inhibition curves by either clorgyline or deprenyl and semicarbazide were also identical to the curves with the other two substrates. These results suggest that carp liver mitochondria contain “classical” MAO and a clorgyline- and deprenyl-resistant amine oxidase and that the classical MAO does not seem to be MAO-A or MAO-B, which are present in mitochondria of most mammalian tissues.     

Monoamine oxidase: To B or not to B?

That the enzyme, monoamine oxidase (E.C. 1.4.3.4. amine: O₂ oxidoreductase, MAO) exists in multiple forms was first suggested by Johnston (1) who studied the effects of the irreversible inhibitor clorgyline on MAO. It has been proposed that MAO can be classified into two types, A and B, according to their inhibitor sensitivity and substrate specificity. Type A MAO was found to be solely responsible for the deamination of 5-hydroxytryptamine (5-HT) and shows high sensitivity to clorgyline, while type B MAO metabolizes 2-phenethylamine (PEA) and benzylamine (BA) and is less sensitive to clorgyline. Subsequently, it was shown that type B MAO is highly sensitive to the irreversible inhibitor deprenyl (2).Recently, the “multiple forms” concept has been questioned (3–5) mainly because of increasing evidence which is contradictory to some earlier findings. As an alternative, another hypothesis was put forward insinuating that MAO is an enzyme with multiple binding sites but only one molecular entity (3,4,6,7). This account will focus on some experimental findings accumulated mainly since 1978 and which, although equivocal, strongly support the “one molecular entity” hypothesis of MAO.     

Evidence for a single catalytic binding site on human brain type B monoamine oxidase

The tricyclic antidepressant drug, amitriptyline, inhibited the B form of human brain mitochondrial monoamine oxidase (MAO) under normal atmospheric conditions in a noncompetitive manner when phenylethylamine (PEA) was used as substrate and competitively when benzylamine (BzNH2) was employed as substrate. In addition, it was also found that PEA and BzNH2 inhibited each other's degradation noncompetitively. Similar results have previously been reported with human platelet MAO. These data suggest that the catalytic binding sites for PEA and BzNH2 on the B form of human brain MAO may be different. Attempts were made to further distinguish these catalytic binding sites on the brain oxidase using the irreversible MAO inhibitors, pargyline and clorgyline. Though these drugs have considerably different affinities for the B form of the oxidase, the degree to which either compound inhibited PEA or BzNH2 deamination was essentially identical. When incubations were performed at elevated oxygen concentrations PEA and BzNH2 became mutually competitive inhibitors of each other's metabolism. Also at the higher levels of oxygen, amitriptyline inhibition of PEA deamination approached a competitive fashion. These results suggest that PEA and BzNH2 share a common catalytic binding site on the B form of MAO and, in addition, bind to an inhibitory site on the reduced form of the oxidase. Accordingly, the data indicate that amitriptyline also binds to both the oxidized and reduced forms of this human brain oxidase.     

NONEXISTENCE OF A TYPE C MONOAMINE OXIDASE IN RAT BRAIN

Abstract— The possible existence of type C MAO, distinct from type A and type B, in circumventricular structures of rat brain was examined by histological studies on the inhibitory effects of clorgyline. a preferential type A MAO inhibitor and deprenyl, a preferential type B inhibitor, on enzyme. Brain slices were preincubated with the inhibitors and then incubated with 5-HT, the substrate for type A MAO, and stained for MAO activity. Deposits of the product formazan were detected in circumventricular structures of slices of brain preincubated with clorgyline and deprenyl at concentrations of 10^-7–10^-4m at room temperature for 5 min. When the slices were preincubated with either of these inhibitors at room temperature for 60 min, strong activity was observed in this region, whereas when they were preincubated with either 10^-5m -clorgyline or 10^-5m -deprenyl for 20 and 30 min at 37°C, no MAO activity was seen in any region of the brain. Thus, at the higher preincubation temperature, lower concentrations of each inhibitor and a shorter preincubation period were required for inhibition of the enzyme. Preincubation for 60 min at 37°C with a combination of 10^-7m -clorgyline and 10^-8m -deprenyl did not inhibit the enzyme in the circumventricular region completely, but at the same temperature, concentrations of 10^-7m of both inhibitors inhibited the enzyme completely in 10min, Thus the effects of the inhibitors are synergistic. These results indicate that the inhibitory effects of the two inhibitors on the enzyme in circumventricular structures of the brain is time- and temperature-dependent. Moreover, the activity seems to be sensitive to deprenyl even when 5-HT is used as substrate. The results do not support the idea of the existence of type C MAO, distinct from type A and type B MAO.     

Characterization of rat pulmonary monoamine oxidase.

The substrate specificities and kinetics of rat lung monoamine oxidase (MAO) have been studied. Utilizing the irreversible MAO inhibitors, clorgyline and deprenyl, rat lung was shown to possess at least two types of MAO, A and B. Tyramine was a substrate for both forms of the enzyme, whereas 5-hydroxytryptamine (5-HT) was a preferred substrate for the A-form. In contrast to most other tissues, 2-phenylethylamine was not solely a B-type substrate for the rat lung MAO and some metabolism by the A-type was apparent $\text{(}\text{B}\text{A}\text{=}\text{80}\text{20}\text{)}$. Using tyramine as substrate the ratio A/B was shown to be $\text{55}\text{45}$. Rat pulmonary MAO-B was inhibited by deprenyl and the kinetics of MAO-A studied. The Km values for the A-form for tyramine, phenylethylamine and 5-HT were relatively similar and were 270, 244 and 170 μM respectively. Whereas, when the A-form was inhibited by clorgyline, the Km values for the B-form were found to differ considerably: 330, 42 and 850 μM for tyramine, phenylethylamine and 5-HT respectively.     

Thermal melting of poly(dA-dT).poly(dA-dT) in methanol-water solutions

1-Methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), a thermal breakdown product of a meperidine-like narcotic analgetic used by drug abusers as a synthetic heroin, causes Parkinsonian symptoms in humans and degeneration of the substantia nigra in monkeys. MPTP is oxidized by brain mitochondrial preparations in a process which is blocked by deprenyl and pargyline, implying catalysis by monoamine oxidase B. The present paper demonstrates that pure MAO B isolated from beef liver oxidizes MPTP 38% as fast as benzylamine with a comparable Km value. Additionally, MAO A, isolated from human placenta, oxidizes MPTP to the same product at about 12% of the rate of kynuramine, again with a comparable Km value. The latter reaction is blocked by clorgyline. Both forms of MAO are progressively inactivated by MPTP by a process which follows first order kinetics. This progressive inactivation and the fact that the activity of MAO B is not significantly regenerated following gel exclusion chromatography suggest the formation of a covalent adduct with enzyme. Thus, MPTP appears to be a suicide inactivator of MAO.     

EFFECTS OF SYMPATHECTOMY ON AXOPLASMIC TRANSPORT OF SELECTED ENZYMES INCLUDING MAO AND OTHER MITOCHONDRIAL ENZYMES

Abstract— Axoplasmic transport in guanethidine sympathectomized and control rats was investigated by monitoring the accumulations of various enzyme activities proximal to a ligature placed on the sciatic nerve. Sympathectomy affected the accumulations of three different mitochondrial enzymes quite differently: the accumulation of monoamine oxidase (MAO, EC 1.4.3.4) activity was inhibited 65% or more, that of hexokinase (HK, EC 2.7.1.1) activity was only inhibited 26%, while accumulation of glutamic dehydrogenase (GDH, EC 1.4.1.3) activity was unaffected by Sympathectomy. Accumulation of AChE (EC 3.1.1.7) activity was depressed 40%, but accumulations of the activities of the lysosomal enzyme, acid phosphatase (acid P'tase, EC 3.1.3.2), and of the cytosolic enzyme, choline acetyltransferase (CAT, EC 2.3.1.6) were unchanged.
Despite impressive inhibition of MAO accumulation, the intrinsic activity of this enzyme in sciatic nerve was unaffected by Sympathectomy. The existence in nerve of isozymes of MAO was demonstrated using the inhibitors clorgyline and deprenyl. Transported MAO activity was almost entirely type A; intrinsic activity was 2/3 type A and 1/3 type B.
The differential response of the accumulations of the three mitochondrial enzyme activities measured was interpreted to indicate the existence, within neurons, of mitochondria with different enzyme complements.     

Deamination of Aliphatic Amines by Monoamine Oxidase A and B Studied Using a Bioluminescence Technique

Deamination of n-octylamine and n-decylamine has been studied in various tissues using a new bioluminescence technique. Selectivity of n-octylamine and n-decylamine as substrates for monoamine oxidase (MAO) A or B has been determined using both clorgyline and (-)-deprenyl inhibition curves and kinetic parameters. Homogenates of rat brain, liver and heart containing predominantly MAO-A or -B were prepared by preincubation for 60 min with (-)-deprenyl or clorgyline (30 nM), respectively. Human placenta (MAO-A) and platelet (MAO-B) were used as reference tissues containing only one MAO form. In tissues (rat liver, brain) containing both MAO forms in equal proportion, inhibition curve studies showed a preference of both substrates for the B form of the enzyme; however, where MAO-A was the major form (rat heart, human placenta), clorgyline was the more effective inhibitor. In the beef brain cortex n-octylamine showed marked preference for MAO-B, whereas n-decylamine was selective toward-MAO-A. Kinetic studies in general supported the picture of greater selectivity of the aliphatic amine substrates for deamination by MAO-B, as reflected by lower Km values for this enzyme type. However, n-octylamine was more selective for MAO-B than n-decylamine in both kinetic and inhibition curve studies. The deamination of these aliphatic amine substrates cannot be explained only by reference to the binary classification of MAO into types A and B.     

Guinea Pig Striatum as a Model of Human Dopamine Deamination: The Role of Monoamine Oxidase Isozyme Ratio, Localization, and Affinity for Substrate in Synaptic Dopamine Metabolism

The kinetic properties of type A and type B monoamine oxidase (MAO) were examined in guinea pig striatum, rat striatum, and autopsied human caudate nucleus using 3,4-dihydroxyphenylethylamine (dopamine, DA) as the substrate. MAO isozyme ratio in guinea pig striatum (28% type A/72% type B) was similar to that in human caudate nucleus (25% type A/75% type B) but different from that in rat striatum (76% type A/24% type B). Additional similarities between guinea pig striatum and human caudate nucleus were demonstrated for the affinity constants (Km) of each MAO) isozyme toward DA. Endogenous concentrations of DA, 3-methoxytyramine, 3,4-dihydroxyphenylacetic acid, and homovanillic acid were also measured in guinea pig and rat striatum following selective type A (clorgyline-treated) and type B (deprenyl-treated) MAO inhibition. In guinea pig, DA metabolism was equally but only partially affected by clorgyline or deprenyl alone. Combined treatment with clorgyline and deprenyl was required for maximal alterations in DA metabolism. By contrast, DA metabolism in rat striatum was extensively altered by clorgyline but unaffected by deprenyl alone. Finally, the deamination of DA in synaptosomes from guinea pig striatum was examined following selective MAO isozyme inhibition. Neither clorgyline nor deprenyl alone reduced synaptosomal DA deamination. However, clorgyline and deprenyl together reduced DA deamination by 94%. These results suggest that the isozyme localization and/or isozyme affinity for DA, rather than the absolute isozyme content, determines the relative importance of type A and type B MAO in synaptic DA deamination. Moreover, based on the enzyme kinetic properties of each MAO isozyme, guinea pig striatum may serve as a suitable model of human DA deamination.     

Histochemical investigation of criteria for the distinction between monoamine oxidase A and B in various species

The superior cervical ganglion (SCG), pineal body (PB), and liver (L) of the rat, rabbit and cat were stained for monoamine oxidase (MAO) A and B by the tetranitro blue tetrazolium (TNBT) and coupled peroxidase ( PerOx ) methods, using 5-hydroxytryptamine (5HT), tryptamine ( Tryp ), tyramine (Tyr), and benzylamine (Bz) as substrates, and clorgyline (Cl) and deprenyl (Dep), both at 10(-7) M, as selective inhibitors. The nodose ganglion (NG) and dorsal root ganglion (DRG) of the rabbit and cat were also studied. The results with rat tissues were consistent with published quantitative findings (SCG, MAO-A much greater than B; PB, MAO-A less than or equal to B; L, MAO-A = B). In the rabbit, the findings with the SCG were similar; the MAO activities of the PB were relatively resistant to both inhibitors; the MAO of the liver required 10(-4) M concentrations of both inhibitors to produce near total inhibition, suggesting that the liver contains an MAO distinct from MAO A and B. All cat tissues examined appeared to contain almost exclusively MAO-B. In this species 5HT, which is generally considered a selective substrate for MAO-A, was oxidized by MAO-B. The findings indicate that criteria for MAO-A, -B, and other subgroups must be defined for each species and tissue.     

Multiple forms of monoamine oxidase in rabbit platelets.

Rabbit platelets were found to contain both types A and B MAO activities. The specific enzymatic activity of rabbit platelet MAO was higher for the substrate serotonin than for phenylethylamine. The K_m's for rabbit platelet MAO indicated that the MAO-B enzyme was similar to human platelet MAO and that both MAO-A and MAO-B enzymes in the rabbit platelet are similar to the corresponding forms in the rabbit brain. The drugs clorgyline and deprenyl confirmed the existence of types A and B MAO in the platelet and furthermore indicated that the type A form accounted for approximately 90% of the total enzymatic activity. Amitriptyline at low (micromolar) concentrations selectively inhibited MAO-B activity in both rabbit platelets and brain.     

Comparative enzymological study of catalytic properties of liver monoamine oxidases in frogs

Comparative enzymological study of catalytical properties of monoamine oxidase (MAO) of liver of the marsh frog Rana ridibunda and common frog Rana temporaria has revealed certain features of similarity and differences between these enzymes. The MAOs from both studied biological sources show catalytic properties resembling those of the classical MAO of terrestrial vertebrates: they deaminate tyramine, tryptamine, serotonin, and benzylamine and do not deaminate histamine, have sensitivity to clorgyline, the specific inhibitor of the MAO A form, and deprenyl, the specific inhibitor of the MAO B form, and are not inhibited by 10⁻² M semicarbazide. Based on data of substrate-inhibitor analysis, a suggestion is put forward about the existence of two molecular forms of the enzyme in liver of the studied frog species. Quantitative interspecies differences have been revealed between liver MAO of Rana ridibunda and Rana temporaria in values of kinetic parameters of reactions of deamination of several substrates and in sensitivity to the inhibitors, deprenyl and clorgyline. In the species Rana temporaria the MAO activity in reaction of deamination of serotonin and benzylamine were virtually identical, whereas in the species Rana ridibunda these parameters for serotonin were almost one order higher than for benzylamine. In the species Rana ridibunda, selectivity of action of deprenyl was expressed many times weaker, while selectivity of the clorgyline—one order of magnitude stronger than in the species Rana temporaria. The catalytic activities towards all studied substrates of liver MAO of both studied amphibian species were several times lower as compared with the enzyme of rat liver.     

Loss of serotonin oxidation as a component of the altered substrate specificity in the Y444F mutant of recombinant human liver MAO A.

To investigate the roles of tyrosyl residues located near the covalent 8alpha-S-cysteinyl FAD in monoamine oxidase A (MAO A) and to test the suggestion that MAO A and plant polyamine oxidase may have structural homology, tyrosyl to phenylalanyl mutants of MAO A at positions 377, 402, 407, 410, 419, and 444 were constructed and expressed in Saccharomyces cerevisiae. All mutant enzymes were expressed and exhibited lower specific activities as compared to WT MAO A using kynuramine as substrate. The lowest specific activities in this assay are exhibited by the Y407F and Y444F mutant enzymes. On purification and further characterization, these two mutants were found to each contain covalent FAD. Both mutant enzymes are irreversibly inhibited by the MAO A inhibitor clorgyline and exhibit binding stoichiometries of 0.54 (Y407F) and 0.95 (Y444F) as compared to 1.05 for WT MAO A. Y444F MAO A oxidizes kynuramine with a k(cat) <2% of WT enzyme and is greater than 100-fold slower in catalyzing the oxidation of phenylethylamine or of serotonin. In contrast, Y444F MAO A oxidizes p-CF(3)-benzylamine at a rate 25% that of WT enzyme. Steady state and reductive half-reaction stopped-flow data using a series of para-substituted benzylamine analogues show Y444F MAO A exhibits quantitative structure activity relationships (QSAR) properties on analogue binding and rates of substrate oxidation very similar to that exhibited by the WT enzyme (Miller and Edmondson (1999) Biochemistry 38, 13670): log K(d) = -(0.37 +/- ()()0.07)V(W)(x0.1) - 4.5 +/- 0.1; log k(red) = +(2.43 +/- 0.19)sigma + 0.17 +/- 0.05. The Y444F MAO A mutant also exhibits similar QSAR properties on the binding of phenylalkyl side chain amine analogues as WT enzyme: log K(i) = (4.37 +/- 0.51)E(S) + 1.21 +/- 0.77. These data show that mutation of Y444F in MAO A results in a mutant that has lost its ability to efficiently oxidize serotonin (its physiological substrate) but, however, exhibits unaltered quantitative structure-activity parameters in the binding and rate of benzylamine analogues. The mechanism of C-H abstraction is therefore unaltered. The suggestion that polyamine oxidase and monoamine oxidase may have structural homology appears to be valid as regards Y444 in MAO A and Y439 in plant polyamine oxidase.